FR2858162A1 - METHOD FOR ACCESSING RESOURCES OF A RADIOCOMMUNICATION SYSTEM, MOBILE TERMINAL AND BASE STATION FOR IMPLEMENTING THE METHOD - Google Patents

Abstract

The invention proposes in particular a mobile terminal comprising: - means for receiving synchronization signals originating from a base station of a radiocommunication system; - means for transmitting, to the base station, requests access to communication resources, at respective instants timed with respect to instants of reception of said synchronization signals; means for determining a level of remoteness with respect to the base station; and means for anticipating the instants of transmission of requests for access to communication resources, as a function of the level of remoteness determined by the means for determining a level of remoteness with respect to the base station.

Description

METHOD FOR ACCESSING RESOURCES OF A SYSTEM OF

  RADIOCOMMUNICATION! MOBILE TERMINAL AND BASE STATION FOR IMPLEMENTING THE METHOD The present invention relates to access to resources of a radio communication system. It relates more particularly to access to resources by remote mobile terminals of the base stations of the radiocommunication system.

  In such radio communication systems, as for example in the Universal Mobile Telecommunication System (UMTS), mobile terminals are arranged to communicate with the network via at least one base station.

  Each base station has a radio coverage area within which it can exchange radio signals with terminals.

  The size of a coverage area depends on several parameters, such as the transmission power of the base station concerned. In fact, below a certain transmission power, the signals transmitted to a radio terminal will be received too weakly for it to be able to decode them. The same is true of the uplink: the maximum transmission power of the terminals may represent a limiting factor for the size of the area where the communication service is possible.

  However, other constraints exist in such systems.

  Some of them may be particularly limiting, so that they impose the strictest delimitation on coverage areas.

  In the UMTS system for example, the strongest constraint is imposed by the access procedure. Each base station has indeed reception windows within which it can detect access requests transmitted by terminals in corresponding transmission time ranges. An access request received by a base station between two successive reception windows will not be correctly detected by the base station.

  A request for access is characterized initially by the transmission of a preamble of 4096 chips (basic units for the transmission of binary information) by a mobile terminal. However, a reception window for such a preamble, corresponding to a "slot" of the random access channel PRACH ("Physical Random Access CHannel"), has 5120 chips. There are therefore 1024 (= 5120-4096) possible positions for receiving a preamble. The base station thus performs correlation calculations for all of these 1024 positions, in order to detect the possible presence of an access request within a reception window.

  In view of the foregoing, it can be shown that the maximum distance a mobile terminal must be relative to a base station, so that the preamble that it transmits is received by the base station in the gateway window. corresponding reception is 40 kilometers only. Beyond this limit, the access request made by the mobile terminal will probably not be received in a transmission window by the base station concerned, which will prevent the access procedure from continuing: the mobile terminal will therefore be allocated no communication resources.

  In some cases, however, it would be particularly interesting to be able to extend the coverage area of a base station to access to establish a communication, especially as the other constraints limiting the coverage area, especially during communication , are much less restrictive. An extension of the coverage can be extremely useful, particularly in maritime areas close to the coast, for example to establish an emergency call.

  It is an object of the present invention to overcome the limitations of the present art, by allowing an increase in the size of the coverage area of the base stations to access.

  Another object of the present invention is to allow access to the network of mobile terminals remote from the base stations of the radio network, in certain cases where necessary, for example to establish emergency calls.

  The invention thus proposes a method of accessing resources of a radiocommunication system comprising at least one base station, from a mobile terminal, the mobile terminal being arranged to issue access requests to the base station to respective transmission instants, the base station being arranged to detect access requests from the mobile terminal in reception windows, each reception window 5 being provided to detect access requests transmitted within a range of times corresponding transmission terminal by a mobile terminal located at a distance from the base station less than a threshold, the reception window following the corresponding transmission time range of a reference time slot. The method comprises the steps of: / a / determining a level of remoteness of the mobile terminal from the base station; / b / conditionally, depending on the distance level determined between the mobile terminal and the base station, use a time interval greater than the reference interval, between the reception windows and the time slots corresponding requests for access by said mobile terminal, so that the base station can detect an access request transmitted by said mobile terminal, in a next reception window, said time interval, the range of corresponding for the moment of issue of the access request.

  Thus, the time interval used between the reception windows and the corresponding transmission time periods of the access requests can be adapted according to the distance level between the mobile terminal of the base station. The distance level considered may correspond to different criteria: it may for example correspond to the fact that the terminal is away from the base station by a distance less than or greater than a distance threshold, or it may take into account an estimate of the distance between the terminal and the base station.

  If the distance separating the terminal from the base station is greater than the threshold, then the time interval used will advantageously be greater than the reference interval, so as to allow the base station to detect the access request. of the terminal, despite the time required for the radio signals carrying the access request to reach the base station. - 4

  The method comprises two alternative embodiments. According to the first embodiment, the use of a time interval greater than the reference interval, between the reception windows and the corresponding transmission time slots of access requests by said mobile terminal, includes an anticipation of the times of transmission of requests for access by said mobile terminal. In this case, it is therefore the mobile terminal that compensates for the additional routing time introduced by the distance between the terminal and the base station. For the base station, everything happens as if the distance separating it from the mobile terminal was below the threshold, because of the anticipation of access requests by the mobile terminal.

  In the second embodiment of the method, the access requests are transmitted by the mobile terminal with a given one of a set of possible signatures, exclusively when the mobile terminal is considered to be remote from the base station by a greater distance. 15 threshold. And the use of a time interval greater than the reference interval, between the reception windows and the corresponding transmission time slots of access requests by said mobile terminal, includes a time lag of reception windows for detecting access requests issued with said given signature. Thus, the base station has reception windows offset with some delay from conventional reception windows, for detecting access requests transmitted from remote terminals and using a particular predetermined signature.

  The invention also proposes a mobile terminal according to the first embodiment of the method and comprising: means for receiving synchronization signals from a base station of a radiocommunication system; means for transmitting, to the base station, access requests to communication resources, at respective times set with respect to times of reception of said synchronization signals; means for determining a level of distance from the base station; and means for anticipating the transmission instants of access requests to communication resources, as a function of the level of distance determined by the means for determining a distance level with respect to the base station.

  The invention also proposes a mobile terminal according to the second embodiment of the method and comprising: means for receiving synchronization signals from a base station of a radiocommunication system; means for transmitting, to the base station, requests for access to communication resources, at respective times set with respect to times of reception of said synchronization signals, the access requests comprising a signature; 15 from a set of possible signatures; means for determining a distance level from the base station.

  The mobile terminal further comprises: means for selecting a signature from the set of possible signatures for issuing access requests comprising said signature, as a function of the distance level determined by the means for determining a level of away from the base station.

  The invention further provides a base station of a radio communication system, in accordance with the second embodiment of the method, and comprising: means for transmitting synchronization signals to mobile terminals; means for detecting access requests transmitted by mobile terminals, in reception windows belonging to a set of at least a first and a second set of reception windows, the access requests including a signature among a set of possible signatures.

  The reception windows of the first set are calibrated with respect to respective transmission instants of the synchronization signals, and the reception windows of the second set are shifted in time with a delay with respect to the reception windows of the first set. The means for detecting access requests transmitted by mobile terminals comprises means for detecting access requests comprising at least one of the possible signatures from the reception windows of the second set, and means for detecting access requests comprising a signature other than said given signature in the reception windows of the first set.

  In an advantageous embodiment of the invention, the changes in the time interval between the reception windows and the corresponding transmission time slots of the access requests are only made when these access requests are intended to establish an emergency call.

  Other features and advantages of the present invention will appear in the following description of nonlimiting exemplary embodiments, with reference to the accompanying drawings, in which: - Figure 1 is a schematic representation of the course in time of the beginning of an access procedure; FIG. 2 is a flowchart schematizing the steps of a method for evaluating the distance between a mobile terminal and a base station according to one embodiment of the invention.

  The following is part of the UMTS radiocommunication system without limiting the scope of the invention, applicable to other systems.

  The access procedure consists first of all for a mobile terminal, called UE ("User Element"), to transmit to the network, on a rising PRACH channel 30, a preamble. This message is sent at the beginning of a time slot or "slot" of 1.33 ms, as illustrated for example in Figure 1, where the preamble is transmitted on the PRACH from the beginning of the slot 12 by the UE. - 7

  The preamble has 4096 chips and consists of 256 repetitions of a code called signature, 16 chips length, selected from a set of 16 signatures available. The signatures are Hadamard codes. The wording of these codes can be found in Section 4.3.3 of Technical Specification TS 25.213, Version 3.7.0, published in December 2001 by 3GPP.

  A UE knows the signatures as well as the slots of the PRACH channel that it can use to request access to a Node B, because this information is broadcast by the Node B on the synchronization channel SCH ("Synchronization CHannel").

  If one is on the side of the radio network, each base station of the system, or Node B according to the terminology used in the UMTS system, seeks to detect if such a preamble has been received from a UE. For this, it performs, as indicated in the introduction and in a manner known per se, correlation calculations between the signals it detects and the possible sequences of preambles, for the different reception positions within a window receiver corresponding to a PRACH channel slot (5120 chips). The receipt of an access request is detected when the Node B correlation calculations indicate that a received digital sequence is that of a PRACH preamble with a certain probability level.

  If a Node B detects the receipt of a preamble, it responds to the UE request for access by transmitting a positive acknowledgment on the downstream AICH (Acquisition Indicator Channel). This acknowledgment has a structure similar to that of the preamble, since it uses a spreading factor equal to 256 and a 16-chip sequence signature. In an exemplary embodiment, a positive acknowledgment on the AICH channel uses a signature identical to the preamble signature, whereas an acknowledgment using an inverted signature with respect to the preamble signature RACH is negative.

  The channel AICH is also aligned in time with the synchronizing down channel SCH, itself divided into 15 slots, and shown in the first line of Figure 1 (Tx Node B). The synchronization signals transmitted at the beginning of each slot on this channel are received by the UE, a flight time (Tv) after their emission by the Node B. In addition, according to the technical specification 25.211, version 5.4. 0, "Physical channels and mapping of transport channels on 5 physical channels (FDD)", published in June 2003 by 3GPP organization (3rd Generation Partnership Project), a time lag of: pa (= 7860) chips between transmission of random access requests on the PRACH channel and receipt by the EU of acknowledgments on the AICH channel. This offset makes it possible to position the transmission slots of the PRACH channel with respect to the synchronization signals transmitted on the SCH channel, as shown in FIG. 1.

  In FIG. 1, the Node B receives the preamble transmitted in the slot 12 of the PRACH by UE (line Tx UE), in a reception window corresponding to the slot 12 of the PRACH channel (line Rx Node B). In example 15 illustrated the flight time (Tv) between the UE and the Node B is sufficiently low for the preamble transmitted by the UE to be received by the Node B within the corresponding reception window. In other words, the UE is located at a distance of less than 40 km from Node B. As a result, Node B will be able to detect receipt of this preamble, and thereby transmit an acknowledgment to the requesting UE. access.

  If the distance separating the UE from the Node B considered is greater than 40 km, the flight time will be too long to allow the preamble transmitted by the EU in a slot of the PRACH to be received by the Node B within the receiving window corresponding to this slot. For example, in FIG. 1, the preamble could be received between the numbered receive windows 12 and 13. Therefore, no preamble would be detected by the Node B since this detection is performed on each receive window only. Indeed, a preamble detection over a period corresponding to more than one reception window, for example to two consecutive reception windows, is not desirable since it would increase the number of possible positions for the reception of a preamble. within this period, which would lead to a considerable increase in the number of correlation computations to be performed by Node B. Consider that a reference time interval (which depends on the flight time between the UE and the Node B, from the foregoing) separates the transmission slots of the preamble by the UE from the reception windows of this same preamble by the Node B. According to the invention, this interval can be modified to obtain an interval of time above the reference interval conditionally, in particular when the UE is distant from the Node B considered, that is to say in the particular case of the UMTS system, when the UE is located at more than 40 km from Node B. To modify this time interval, it is possible to play on the transmission instants of the preambles or on the times of reception of these preambles.

  In a first embodiment, the increase in the time interval results from an anticipation of the transmission of the preamble by a UE remote from the Node B. For example, when the transmission of the preamble by the UE in 15 slot 12 would normally result in a preamble reception between the receiving windows 12 and 13 at the Node B, the terminal will actually transmit the preamble with a Ta advance from the beginning of the slot 12. Therefore, the preamble will well received by the Node B within its reception window 12. If it is desired, for example, to be able to detect the access requests issued by mobile terminals located at a distance from the Node B between 40 and 80 km preferably, Ta will be chosen so that the anticipation corresponds to 1024 chips.

  In this embodiment, only the UE is aware of its distance from the Node B, whereas for the latter, everything happens as if the UE were within 40 km (since seen from Node B, the preamble is normally received in a reception window). Subsequently, the UE will shift its transmission and reception windows by the value of Ta, so as to always compensate for the delay introduced by the additional distance to be traveled for the signals it transmits and receives. The emission windows of the UE will be advanced in the time of Ta, while the reception windows of the UE will be shifted with a delay of Ta. No modification of the transmit and receive windows is necessary at Node B in this case. -

  According to a second embodiment, the time interval between the transmission slots and the access preamble reception windows is greater than the reference time interval, due to the time lag of certain windows of at reception of the Node B. Advantageously, the reception windows, thus permanently shifted in time, correspond to reception windows in which the Node B attempts to detect preambles using one or more particular signatures among the different signatures. possible. Indeed, in this embodiment, one or more signatures are exclusively used to code the preambles emanating from UEs distant from the Node B of more than 40 km.

  So we have at Node B, several sets of reception windows that coexist. A set of reception windows is positioned in time in a conventional manner, that is to say respecting the reference time interval with respect to the transmission of the preambles on the PRACH. This set allows Node B to detect preambles emitted by UEs near Node B with an unreserved signature. Another set of reception windows is time-shifted with respect to the first set of windows and serves to detect exclusively the preambles containing a signature reserved for access requests made by UEs remote from Node B. Receiving Node B, in a window shifted in time so as to compensate for the increase in the flight time for the remote terminals, a preamble containing a reserved signature will correctly interpret the reception of the preamble. The flight time considered by the Node B will be the actual flight time, ie the apparent flight time (Tv) plus the value of the time shift used for this window. Subsequently, the signals are exchanged between the UE and the Node B taking into account this actual flight time.

  It is possible to provide a larger number of sets of reception windows to detect preambles issued by more or less distant UEs and including respective reserved signatures. These sets of reception windows have different time offsets between them to allow the detection of access requests by UEs more or less distant from the Node B. For example, an UE distant from 40 to 80 km d a Node B will use a first reserved signature, while an UE more than 80 km away from Node B will use a second reserved signature. The 5 reception windows on which the preambles using the first signature are detected are shifted by 1024 chips in time compared to the conventional reception windows, and those for receiving the preambles using the second signature have an offset of 2048 chips. Depending on the window on which the Node B detects a preamble and o10 depending on the signature used for this preamble, the Node B will then have an approximation of the distance of the UE requesting access. This nevertheless assumes a fairly precise knowledge of the distance separating the UE from the Node B, which can be acquired for example according to one of the methods described below.

  In an advantageous embodiment, the choice of a time interval between the transmission and reception slots of the access requests is made conditional, according to other criteria, in addition to the distance separating the UE. In particular, remote access may be reserved for UEs attempting to make an emergency call. For this purpose, the UE considered can anticipate its transmission of the preamble according to the first embodiment of the invention described, or use a signature reserved for remote emergency calls according to the second embodiment of the invention, only when the access request corresponds to the establishment of an emergency call.

  To determine if a UE is remote from a Node B, especially if it is at a distance greater than 40 km, UE has various means, depending on the precision sought.

  It can for example deduce its distance from the analysis of certain parameters. In particular, UE can calculate the reception power of the signals it receives from Node B, in a manner known per se. Thus, a signal received with low power can be interpreted by the UE as emanating from a Node B located at a great distance from it. A propagation profile can also be established in a manner known per se. The analysis of this propagation profile by the UE then leads to determining a distance from the Node B. For example, if the analysis of the propagation profile reveals the presence of a reduced number of propagation paths, the paths with significant delays, this can be interpreted as a sign of a large distance between the UE and the Node B. The various parameters mentioned above will advantageously be calculated from the estimation of the data received on the CPICH common physical channel ( "Common Pilot CHannel") issued by Node B and comprising a sequence of symbols known from the UE.

  If the signals of several Nodes B are received by the UE, the latter can advantageously combine parameters from these different Nodes B. For example, if the UE receives a signal of very low power on each of the common channels emitted by the Node B, it can be deduced that it is at a significant distance from all the Nodes B of the network. On the other hand, if one or more signals are received at high power from some Nodes B, the UE will probably be close to these Nodes B. A power threshold can be used to determine if the distance from the UE to at a Node B is greater than 40 km.

  Another embodiment, illustrated in FIG. 2, can advantageously be used to determine the distance between a UE and a Node B, in order to determine whether the access procedure adapted to the remote accesses, as described above, must be done or not.

  According to this embodiment, the UE wishing to access the network begins by making a conventional access request by transmitting a preamble on the PRACH channel, as indicated above. A power ramp may be used by the UE to retransmit the preamble regularly with, for each new transmission, a transmission power increased compared to the previous transmission, as long as its request for a transmission has not been fulfilled. access (step 20). This method makes it possible to improve the detection of the preamble by the Node B concerned, especially in the case where the low transmission power of the first transmissions is at the origin of the absence of detection on the PRACH. This process can be repeated until the UE reaches a predetermined maximum transmit power Pmax.

  If a response is received by the UE during this step, i.e. if the UE receives a positive acknowledgment on the AICH in response to the request issued on the PRACH with a power less than or equal to P max this means that, under normal transmission conditions, Node B is able to detect the preamble emitted by the UE. In other words, the UE is located at a sufficiently small distance from the Node B, that is, typically within 40 km of the Node B (step 22). In this case, the access procedure can continue normally (step 23), that is, the UE will transmit to Node B an access message following the preamble (see section 5.2. 2.1.3 of the aforementioned Technical Specification 25.211), then Node B will allocate communication resources to the EU.

  On the contrary, if no response is received by the UE after it has sent a preamble at maximum power Pmax, or even a set of preambles 15 according to a power ramp up to Pmax, then UE repeats its request for access on the PRACH channel by anticipating this request by a value of a feedrate Ta, relative to the start of the transmission slot on the PRACH, as determined in coherence with the synchronization provided by the Node B, as described above (step 24). This new preamble transmission can be made directly at maximum power Pmax or at reduced power, then repeated with increased power along a power ramp, possibly up to reach Pmax as in the previous case.

  The advance in time Ta used to anticipate the new access request depends on the precision that one wishes to have on the distance separating the UE from the Node B. In an advantageous embodiment, Ta corresponds to an advance of 1024 chips, so that the new access request will be detected by Node B, if the UE is between 40 and 80 km from the Node B considered.

  If a response to the new request is received by the UE from the Node B (step 26), in the form of a positive acknowledgment for example, this means that the digital preamble sequence has been detected by the Node B in one of its reception windows. The flight time between the UE and the Node B is therefore such that the preamble transmitted with an anticipation of Ta will be received in a reception window of the Node B, that is to say that the UE is well received. located in the range of distances associated with the anticipation of Ta, ie for example 40-80 km for an anticipation of the emission slots of 1024 chips. On receipt of the acknowledgment, the UE can then consider itself to be distant from the Node B in a range of distances consistent with the anticipation Ta (step 28).

  On the other hand, in the case where no response is received to the UE advance access request, even with a maximum transmission power Pmax, the anticipation can be increased again by the value Ta, for 10 cover a range of greater distances than in the previous case (step 24). A new access request will be made again by the EU, but with an anticipation of 2.Ta.

  After a number n of repetitions of steps 24 and 27 of the flowchart illustrated in FIG. 2, that is to say after a number of anticipations made for the transmission slots of the preamble, without the UE has received an acknowledgment from Node B, the advance in time reaches the value of n.Ta.

  As long as n.Ta has a value less than a maximum anticipation value Ta max, a new anticipation can be made for a new access request by the UE, in accordance with what is described above. When the value Ta max is reached, the access procedure is stopped.

  Advantageously, Ta max corresponds to an anticipation of the transmission slots of the PRACH of a value of less than 5120 chips, so as not to lead to a situation where the reception window thus anticipated is substituted for the reception window which the precedes in normal times. For example, Ta max may correspond to an anticipation of 4096 (= 51201024) chips, which can cover the range of distances 160-200 km. It is of course possible to set a lower maximum anticipation. Such a method can then, after a certain number of repetitions of the preamble 30 regularly anticipated by an advance of Ta, detect an access request sent by a UE located within a 200 km radius of the Node B. D Other variants of this method of determining the distance are also possible, for example by not anticipating each new access request of the same anticipation value Ta, or by covering only certain determined ranges of distances. .

  At the end of the preceding steps, the UE will anticipate its transmission windows for its access requests on the PRACH channel of the value n.Ta, then it will anticipate its windows of emission and will introduce a delay in its windows. receiving the same value n.Ta for its exchanges of traffic or data with the Node B, according to one embodiment of the invention. According to the alternative embodiment of the invention, the UE will use a particular signature for its preamble, so that it is received at Node B in a time-shifted reception window of n. conventional reception windows.

  Knowledge of window anticipations or offsets thus makes it possible to ensure correct establishment and maintenance of dedicated channels for the transmission of voice or data traffic.

  According to an advantageous embodiment, after having acquired an approximate knowledge of the distance separating it from the Node B, for example by the method illustrated in FIG. 2, the UE transmits to the Node B an indication relating to this approximation of the distance. . This can be accomplished by transmitting to Node B, the number n of loops performed in the above method, in the access message that follows receipt of a positive acknowledgment by the UE. This indication can then be exploited by the network, for example for purposes of locating the UE.

  When the EU itself has localization means, for example a receiver based on the GPS positioning system ("Global Positioning System"), it can advantageously transmit the evaluation it has made of its position at Node B. This transmission can be performed for example by inserting the evaluation of the position of the UE in the message transmitted on the random access channel PRACH, following the acknowledgment of the access preamble. - 16

Claims (23)

  A method of accessing resources of a radio communication system comprising at least one base station from a mobile terminal, the mobile terminal being arranged to issue access requests to the base station at times of time. respective transmissions, the base station being arranged to detect access requests from the mobile terminal in reception windows, each reception window being arranged to detect access requests transmitted in a corresponding transmission time range. by a mobile terminal located at a distance from the base station below a threshold, the reception window following the corresponding transmission time range of a reference time slot, the method comprising the following steps: determining a level of remoteness of the mobile terminal from the base station; / b / conditionally, depending on the distance level determined between the mobile terminal and the base station, to use a time interval greater than the reference interval, between the reception windows and the time slots d corresponding transmission of access requests by said mobile terminal, so that the base station can detect an access request transmitted by said mobile terminal, in a next reception window, said time interval, the range corresponding for the moment of issue of the access request.   The method of claim 1, wherein step Ib is performed when determining the remoteness level of the mobile terminal from the base station indicates that the mobile terminal is located at a distance from the base station. greater than said threshold.   The method according to claim 1 or 2, wherein the use of a time interval greater than the reference interval, between the reception windows and the corresponding transmission time ranges of the requests of access by said mobile terminal, comprises an anticipation of the times of transmission of requests for access by said mobile terminal.   The method of claim 1 or 2, wherein the access requests are issued by the mobile terminal with a given one of a set of possible signatures, exclusively when the mobile terminal is considered remote from the base station. a distance greater than said threshold, and in which the use of a time interval greater than the reference interval, between the reception windows and the corresponding transmission time slots of access requests by said terminal mobile, includes a time shift of the reception windows for detecting the access requests issued with said given signature.   The method of any of the preceding claims, wherein said time interval used between the receive windows and the corresponding transmit time periods of the access requests by said mobile terminal, depends on the distance between the mobile terminal and the base station.   The method of any of the preceding claims, wherein said time interval used between the receive windows and the corresponding transmit time slots of the access requests by said mobile terminal is greater than reference time interval of a value lower than the duration of a reception window.   7. A method according to any one of the preceding claims, wherein determining the remoteness level of the mobile terminal relative to the base station comprises an estimate by the mobile terminal of at least one parameter among: a level of power of a signal received from the base station, a propagation profile between the mobile terminal and the base station, propagation delays between the mobile terminal and the base station, a power level of received signals respectively from a set of base stations. - 18   8. A method according to any one of the preceding claims, wherein the determination of the level of distance of the mobile terminal from the base station comprises the following steps: Here issue a request for access to an instant of transmission from the mobile terminal, so that it can be detected by the base station in a corresponding reception window; / dl if no response to the access request has been received at the mobile terminal, repeating the transmission of an access request at an anticipated time of emission with respect to the corresponding reception window; / e / deduce that the mobile terminal is at a distance from the base station greater than said threshold, if a response to the access request is received at the mobile terminal at the end of step / d /.   The method of any one of claims 1 to 7, wherein determining the remoteness level of the mobile terminal from the base station comprises the steps of: issuing an access request at a time of transmitting from the mobile terminal such that it can be detected by the base station in a corresponding reception window; / g / if no response to the access request has been received at the mobile terminal, repeating the transmission of an access request at an anticipated transmission time with respect to the corresponding reception window; / hl repeat the step Igl by further anticipating the transmission time with respect to the corresponding reception window, as long as no response to the access request has been received at the mobile terminal and an anticipation maximum has not been reached for the time of issue of the access request; and / deriving an estimate of the distance between the mobile terminal and the base station from a number of repetitions of the step / g / performed. - 19   The method of any one of the preceding claims, wherein step / b / is performed only when the access request is to establish an emergency call.   The method of any of the preceding claims, wherein the level of remoteness of the mobile terminal from the base station is determined by the mobile terminal and transmitted to the base station for further processing. 12. in in base 13.   Method according to any one of the preceding claims, wherein the mobile terminal is able to evaluate its geographical position, and which it transmits the geographical position that it has evaluated to the station of in an access message.   A mobile terminal comprising: - means for receiving synchronization signals from a base station of a radio communication system; Means for transmitting, to the base station, requests for access to communication resources, at respective times set with respect to times of reception of said synchronization signals; means for determining a distance level from the base station; and means for anticipating the times of transmission of access to communication resources, as a function of distance determined by the means for determining distance from the base station.   requests of the level one level 14. Mobile terminal according to claim 13, wherein the means for anticipating the times of transmission of requests for access to communication resources, anticipate said times of issue of requests for access when the means to determine a distance level from the base station indicate that the mobile terminal is away from the base station by a distance greater than a threshold.   The mobile terminal of claim 13 or 14, wherein the means for determining a distance level from the base station comprises means for estimating a distance between the mobile terminal and the base station, and wherein The anticipation performed by the means for anticipating the transmission times of requests for access to communication resources depends on the estimated distance between the mobile terminal and the base station.   The mobile terminal of any one of claims 13 to 15, wherein the means for determining a distance level from the base station comprises means for estimating at least one parameter from: a power level of a signal received from the base station, a propagation profile between the mobile terminal and the base station, propagation delays between the mobile terminal and the base station, a signal power level received from a set respectively. of 15 base stations of the radiocommunication system.   Mobile terminal according to any one of claims 13 to 16, wherein the means for determining a distance level with respect to the base station comprise: means for transmitting, to the base station, a Requesting access to communication resources, at an instant of emission set with respect to a respective instant of reception of a synchronization signal transmitted by the base station; means for repeating the transmission of an access request in advance, if no response to the access request has been received at the mobile terminal; means for deducing that the mobile terminal is at a distance from the base station greater than a threshold, if a response to the access request is received at the mobile terminal after the repetition of the access request; in advance.   Mobile terminal according to any one of claims 13 to 17, wherein the means for determining a distance level with respect to the base station comprise: means for transmitting, to the base station, a Requesting access to communication resources, at an instant of emission calibrated with respect to a respective instant of reception of a synchronization signal transmitted by the base station; means for repeating the transmission of an access request by anticipating each time the transmission time of the access request, as no response to the access request has been received mobile terminal and maximum anticipation has not been reached; means for deriving an estimate of the distance between the mobile terminal and the base station from a number of repetitions performed by said means for repeating the transmission of an access request by anticipating in each case the moment of issue of the access request.   19. The mobile terminal as claimed in claim 13, wherein said means for anticipating transmission times for access requests to communication resources, as a function of the level of distance determined by the means for determine a level of distance from the base station, are implemented only when the access requests are to establish an emergency call.   The mobile terminal according to any one of claims 13 to 19, further comprising means for transmitting to the base station information relating to the distance level determined by the means for determining a distance level with respect to the base station.   21. Mobile terminal according to any one of claims 13 to 20, further comprising means for evaluating its geographical position, and means for transmitting said geographical position to the base station 30 in an access message. 22.   A mobile terminal comprising: means for receiving synchronization signals from a base station of a radio communication system; means for transmitting, to the base station, requests for access to communication resources, at respective times set with respect to times of reception of said synchronization signals, the access requests comprising a signature; among a set of possible signatures; means for determining a level of distance from the base station; the mobile terminal further comprising: means for selecting a signature from among the set of possible signatures for issuing access requests comprising said signature, as a function of the distance level determined by the means for determining a distance level compared to the base station.   The mobile terminal of claim 22, wherein the means for determining a distance level from the base station comprises means for determining whether the mobile terminal is away from the base station by a distance greater than one. threshold, and wherein the means for selecting a signature from the set of possible signatures comprises means for selecting a given signature for issuing access requests comprising said given signature, exclusively when the means for determining a level of remoteness relative to the base station indicate that the mobile terminal is remote from the base station by a distance greater than said threshold.   The mobile terminal of claim 22 or 23, wherein the means for determining a distance level from the base station comprises means for estimating at least one parameter among: a power level of a signal received from the base station, a propagation profile between the mobile terminal and the base station, propagation delays between the mobile terminal and the base station, a signal power level received respectively from a set of base stations of the radiocommunication system.   Mobile terminal according to any one of claims 22 to 24, wherein the means for determining a level of distance from the base station comprise: means for transmitting, to the base station, a request for access to communication resources, at an instant of emission set with respect to a respective instant of reception of a synchronization signal transmitted by the base station; means for repeating the transmission of an access request in advance, if no response to the access request has been received at the mobile terminal; means for deriving that the mobile terminal is at a distance from the base station greater than a threshold, if a response to the access request is received at the mobile terminal at the end of the repetition of the request for early access.   The mobile terminal of any one of claims 22 to 25, wherein said means for selecting a signature from the set of possible signatures for issuing access requests comprising said signature, as a function of the determined distance level. by the means for determining a level of distance from the base station, are implemented only when access requests are intended to establish an emergency call.   27. Base station of a radio communication system, comprising: means for transmitting synchronization signals intended for mobile terminals; means for detecting requests for access to communication resources, transmitted by mobile terminals, in reception windows belonging to a set of at least a first and a second set of reception windows, requests for access comprising a signature from a set of possible signatures; In which the reception windows of the first set are calibrated with respect to the respective transmission instants of the synchronization signals, and the reception windows of the second set are offset in time with a delay with respect to the reception windows of the first set; and wherein the means for detecting access requests issued by mobile terminals comprises means for detecting access requests comprising at least one of the possible signatures set in the reception windows of the second set, and means for detecting access requests comprising a signature other than said signature given in the reception windows of the first set.